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Advances in understanding the physiologic functions of the tumor necrosis factor superfamily (TNFSF) of ligands, receptors, and signaling networks are providing deeper insight into pathogenesis of infectious and autoimmune diseases and cancer. LIGHT (TNFSF14) has emerged as an important modulator of critical innate and adaptive immune responses. LIGHT and its signaling receptors, herpesvirus entry mediator (TNFRSF14), and lymphotoxin ß receptor, form an immune regulatory network with two co-receptors of herpesvirus entry mediator, checkpoint inhibitor B and T lymphocyte attenuator, and CD160. Deciphering the fundamental features of this network reveals new understanding to guide therapeutic development. Accumulating evidence from infectious diseases points to the dysregulation of the LIGHT network as a disease-driving mechanism in autoimmune and inflammatory reactions in barrier organs, including coronavirus disease 2019 pneumonia and inflammatory bowel diseases. Recent clinical results warrant further investigation of the LIGHT regulatory network and application of target-modifying therapeutics for disease intervention.

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BACKGROUNDSevere coronavirus disease 2019 (COVID-19) is associated with a dysregulated immune response, which can result in cytokine-release syndrome and acute respiratory distress syndrome (ARDS). Patients with COVID-19-associated ARDS have elevated free serum levels of the cytokine lymphotoxin-like inducible protein that competes with glycoprotein D for herpesvirus entry on T cells (LIGHT; also known as TNFSF14). Such patients may benefit from LIGHT-neutralization therapy.METHODSThis randomized, double-blind, multicenter, proof-of-concept trial enrolled adults hospitalized with COVID-19-associated pneumonia and mild to moderate ARDS. Patients received standard of care plus a single dose of a human LIGHT-neutralizing antibody (CERC-002) or placebo. The primary endpoint was the proportion of patients receiving CERC-002 who remained alive and free of respiratory failure through day 28. Safety was assessed via adverse event monitoring.RESULTSFor most of the 83 enrolled patients, standard of care included systemic corticosteroids (88.0%) or remdesivir (57.8%). A higher proportion of patients remained alive and free of respiratory failure through day 28 after receiving CERC-002 (83.9%) versus placebo (64.5%; P = 0.044), including in patients 60 years of age or older (76.5% vs. 47.1%, respectively; P = 0.042). Mortality rates were 7.7% (CERC-002) and 14.3% (placebo) on day 28 and 10.8% and 22.5%, respectively, on day 60. Treatment-emergent adverse events were less frequent with CERC-002 than placebo.CONCLUSIONFor patients with COVID-19-associated ARDS, adding CERC-002 to standard-of-care treatment reduces LIGHT levels and might reduce the risk of respiratory failure and death.TRIAL REGISTRATIONClinicalTrials.gov NCT04412057.FUNDINGAvalo Therapeutics.

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Many coronavirus disease 2019 (COVID-19) patients demonstrate lethal respiratory complications caused by cytokine release syndrome (CRS). Multiple cytokines have been implicated in CRS, but levels of tumor necrosis factor superfamily 14 (TNFSF14) (LIGHT) have not been previously measured in this setting. In this study, we observed significantly elevated serum LIGHT levels in hospitalized COVID-19 patients compared to healthy age- and gender-matched control patients. The assay detected bioavailable LIGHT unbound to the inhibitor Decoy receptor-3 (DcR3). Bioavailable LIGHT levels were elevated in patients both on and off ventilatory support, with a trend toward higher levels in patients requiring mechanical ventilation. In hospitalized patients over the age of 60, who exhibited a mortality rate of 82%, LIGHT levels were significantly higher (P = 0.0209) in those who died than in survivors. As previously reported, interleukin 6 (IL-6) levels were also elevated in these patients, with significantly (P = 0.0076) higher levels observed in patients who died than in survivors, paralleling the LIGHT levels. Although attempts to block IL-6 binding to its receptor have shown limited success in COVID-19 CRS, neutralization of LIGHT may prove to be more effective owing to its more central role in regulating antiviral immune responses. The findings presented here demonstrate that LIGHT is a cytokine which may play an important role in COVID-19 patients presenting with acute respiratory distress syndrome (ARDS) and CRS and suggest that LIGHT neutralization may be beneficial to COVID-19 patients.

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BACKGROUND: Trastuzumab is a monoclonal antibody which demonstrates efficacy for HER2 positive breast cancer patients. Recently, an increased incidence of brain metastasis in trastuzumab-treated patients has been reported. The reason for this may be the effectiveness of systemic trastuzumab allowing patients to survive longer thus providing time for brain metastases to develop, along with the lack of penetration of systemic therapies through the blood brain barrier. In recent years, several administration routes to the brain have been evaluated. Albeit advances in the field, there is still a need for improved delivery of therapeutic antibodies to the brain. To address this challenge, we have developed two gene therapy-based methods enabling continuous secretion of active trastuzumab in the brain. METHODS: We have developed two gene therapy approaches for the delivery of the therapeutic anti-HER2 monoclonal antibody, trastuzumab, to the brain. We utilized the helper dependent adenovirus vector, containing trastuzumab light and heavy chains coding sequences (HDAd-trastuzumab). In the first approach, we used the Transduced Autologous Restorative Gene Therapy (TARGT) platform, in which dermal fibroblasts of human and mouse origin, are ex-vivo transduced with HDAd-trastuzumab vector, rendering continuous secretion of active trastuzumab from the cells locally. These genetically engineered cells were subsequently implanted intracranially to mice, contralateral to HER2 positive breast carcinoma cells inoculation site, enabling continuous secretion of trastuzumab in the brain. In the second approach, we used the same HDAd-trastuzumab viral vector, directly injected intracranially, contralateral to the HER2 positive breast carcinoma cells inoculation site. Both methods enabled therapeutic concentrations of local in-vivo production of active trastuzumab in a mouse model of brain metastatic breast cancer. RESULTS: Trastuzumab secreted from the TARGT platform demonstrated in-vitro affinity and immune recruitment activity (ADCC) similar to recombinant trastuzumab (Herceptin, Genentech). When implanted in the brain of HER2 positive tumor-bearing mice, both the TARGT platform of dermal fibroblasts engineered to secrete trastuzumab and direct injection of HDAd-trastuzumab demonstrated remarkable intracranial tumor growth inhibitory effect. CONCLUSIONS: This work presents two gene therapy approaches for the administration of therapeutic antibodies to the brain. The TARGT platform of dermal fibroblasts engineered to secrete active trastuzumab, and the direct injection of HDAd-trastuzumab viral vector, both rendered continuous in-vivo secretion of active trastuzumab in the brain and demonstrated high efficacy. These two approaches present a proof of concept for promising gene therapy based administration methods for intracranial tumors as well as other brain diseases.

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BACKGROUND: Rheumatoid arthritis (RA) is a symmetric inflammatory polyarthritis associated with high concentrations of pro-inflammatory, cytokines including tumor necrosis factor (TNF)-α. Adalimumab is a monoclonal antibody (mAb) that binds TNF-α, and is widely used to treat RA. Despite its proven clinical efficacy, adalimumab and other therapeutic mAbs have disadvantages, including the requirement for repeated bolus injections and the appearance of treatment limiting anti-drug antibodies. To address these issues, we have developed an innovative ex vivo gene therapy approach, termed transduced autologous restorative gene therapy (TARGT), to produce and secrete adalimumab for the treatment of RA. METHODS: Helper-dependent (HD) adenovirus vector containing adalimumab light and heavy chain coding sequences was used to transduce microdermal tissues and cells of human and mouse origin ex vivo, rendering sustained secretion of active adalimumab. The genetically engineered tissues were subsequently implanted in a mouse model of RA. RESULTS: Transduced human microdermal tissues implanted in SCID mice demonstrated 49 days of secretion of active adalimumab in the blood, at levels of tens of microgram per milliliter. In addition, transduced autologous dermal cells were implanted in the RA mouse model and demonstrated statistically significant amelioration in RA symptoms compared to naïve cell implantation and were similar to recombinant adalimumab bolus injections. CONCLUSIONS: The results of the present study report microdermal tissues engineered to secrete active adalimumab as a proof of concept for sustained secretion of antibody from the novel ex vivo gene therapy TARGT platform. This technology may now be applied to a range of antibodies for the therapy of other diseases.

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Protein drugs are currently delivered by bolus injection and although treatment frequently is successful, these methods also have major drawbacks, which call for the development of alternative technologies allowing prolonged delivery of these drugs. We developed a new ex vivo gene therapy platform called Transduced Autologous Restorative Gene Therapy (TARGT) for sustained long term production and secretion of autologous therapeutic proteins. A biopsy of dermal tissue taken from the patient is transduced ex vivo with a viral vector encoding the required gene under a constitutive promoter. Following measurement of protein secretion ex vivo, the transduced dermal tissue is implanted back into the patient, where it secretes the therapeutic protein into the circulation for several months or longer. A major hurdle to this approach is potential immunogenicity of the transduced tissue following implantation. In this paper we describe the preclinical and early clinical development of this technology, which allowed for overcoming these hurdles. To that end, we have used the helper dependent (HD) adenoviral vector with newly designed expression cassette containing genetic elements to optimize transgene expression. Moreover, we have developed procedures for TARGT tissue implantation, with measures to improve engraftment and reduce inflammation and rejection. Implantation of human TARGT to severe combined immune deficient (SCID) mice indicated long-term production of active proteins in the blood. Preliminary results of a clinical trial from two anemic end-stage renal disease patients, implanted with TARGTs expressing the human erythropoietin (EPO) gene, demonstrated prolonged secretion with physiologic blood level of the hormone and hemoglobin maintenance in the desired range, for a period of at least 5 months without exogenous EPO administration. We believe that the TARGT technology has the potential to become a platform for the sustained delivery of therapeutic proteins in various clinical indications.

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